KR20160082192A - LED driving circuit - Google Patents

Abstract

According to an embodiment, provided is an LED driving circuit which comprises: an LED load; a rectification unit configured to rectify AC power into DC power; a driving unit configured to form a first current path to input the DC power to the LED load and charge a first current outputted from the LED load; and a control circuit unit configured to protect an over-current and an over-voltage from the first current and a second current which is fed back from an output terminal of the driving unit when the first current path is formed and to control the driving unit to form the first current path. Therefore, the LED driving circuit can supply a constant current by the LED load instead of an expensive component such as a constant current driving integrated circuit, a micro processor or the like.

Description

LED driving circuit < RTI ID = 0.0 >

An embodiment relates to an LED driving circuit.

A light emitting diode (hereinafter, referred to as 'LED') is a light emitting device manufactured using a semiconductor manufacturing process. Since the phenomenon of light emission occurred when a voltage was applied to a semiconductor device in the 1920s, And research and development related to light emitting diodes have been made steadily.

In recent years, due to various advantages of LEDs, there has been a growing interest in LEDs for illumination that have enough optical characteristics to replace conventional incandescent lamps, and products replacing LEDs in fluorescent lamps and incandescent lamps used in existing lighting systems are being released.

In recent years, LED lighting systems having brightness characteristics comparable to those of existing lighting devices have been announced. However, much research is needed in the field of LED driving circuits.

On the other hand, since the LED is a current driven device, a constant current must be supplied to maintain the same brightness of the LED.

In order to achieve this, a constant current drive circuit is generally constructed by using a constant current drive integrated circuit (IC) or a microprocessor. However, in recent years, expensive components such as a constant current drive integrated circuit and a microprocessor are not used, Is underway.

It is an object of the present invention to provide an LED driving circuit which can drive an LED without using an expensive component such as a constant current drive integrated circuit (IC) and a microprocessor.

The LED driving circuit according to the embodiment includes a rectifying part for rectifying the LED load and the ac power to the dc power source, a first current path for inputting the dc power to the LED load, and a first current output from the LED load And a second current path which is connected between the first current path and the second current path and which protects the overcurrent and the overvoltage based on the second current and the first current fed back from the output terminal of the driving unit, And may include a control circuit portion.

The LED driving circuit according to the embodiment includes a rectifying part for rectifying the LED load and the ac power to the dc power source, a first current path for receiving the dc power by the LED load, And a controller for controlling the driving unit so that the first current outputted from the LED load is blocked based on a second current fed back from an output terminal of the driving unit, Wherein the control circuit unit controls the driving unit to input the dc power to the LED load based on the first current charged from the driving unit for the initial start of the LED load, 1 current path can be formed.

The LED driver circuit according to the embodiment has an advantage that a constant current can be supplied to an LED load instead of an expensive component such as a constant current drive integrated circuit or a microprocessor.

Further, the LED driver circuit according to the embodiment has an advantage that a constant current can be supplied to the LED load even when the switch is turned off using an inductor.

1 is a control block diagram showing a control configuration of an LED driving circuit according to an embodiment.
2 is a circuit diagram showing an LED driving circuit according to an embodiment.
3 is a current path diagram showing a first current path of the LED driver circuit according to the embodiment.
4 is a current path diagram showing a second current path of the LED driver circuit according to the embodiment.

Hereinafter, embodiments will be described in detail with reference to the drawings.

1 is a control block diagram showing a control structure of an LED driving circuit according to an embodiment, and Fig. 2 is a circuit diagram showing an LED driving circuit according to an embodiment.

1 and 2, the LED driving circuit 100 may include an LED load 110, a rectifying unit 120, a filter unit 130, a driving unit 140, and a control circuit unit 150.

The LED load 110 may be a light emitting device including a light emitting diode or the like, but is not limited thereto.

Also, the LED load 110 may be a plurality of light emitting diodes connected in series and in parallel, but is not limited thereto.

The rectifying unit 120 may rectify different phases of the input ac power source Vac to the dc power source Vdc on the same level.

At this time, the rectifying unit 120 may include, but is not limited to, bridge diodes d1, d2, d3, and d4.

Although the rectifying section 120 is shown and described as including four diodes in the embodiment, four FETs may be used, and the FETs may include, but are not limited to, a drive IC that outputs a gate signal when using FETs .

The filter unit 130 may include an LC filter for filtering noise components contained in the dc power source Vdc rectified by the rectification unit 120 and may include a dc power source Vdc filtered to the input of the LED load 110, Can be supplied.

The driving unit 140 may form a first current path so that the dc power source Vdc is input to the LED load 110. [

The driving unit 140 includes an inductor L for charging the first current I1 output to the output terminal of the LED load 110, a diode connected between the output terminal of the inductor L and the input terminal of the LED load 110 And the output terminal of the switch Q and the switch Q that are connected in parallel to the inductor L and the diode D and are connected in parallel to each other under the control of the control circuit unit 150 to form the first current path, And a shunt resistor R connected to the shunt resistor R.

The inductor L charges the first current I1 outputted from the LED load 110 when the switch Q is switched on and the first current path is formed so that the switch Q is turned on during the switching- , And supply the stored first current I1 to the LED load 110 via the diode D. [

At this time, the inductor L may supply the first current I1 charged to the control circuit part 150 so that the first current path is formed.

The diode D may be connected to the anode of the inductor L and the cathode may be connected to the LED load 110.

That is, the diode D may form a second current path for supplying the LED load 110 with the first current I1 supplied from the inductor L.

The switch Q may include at least one of a FET and a BJT, which is represented as an FET in the embodiment and is not limited thereto.

That is, the switch Q may have a drain connected to the output terminal of the inductor L, a gate connected to the output terminal of the control circuit unit 150, and a drain connected to the shunt resistor R. [

The switch Q may switch on or off by receiving a switching on or off signal from the control circuit 150 to the gate.

The switch Q may form the first current path through which the first current I1 flows through the LED load 110, the inductor L and the shunt resistor R during the switching on operation.

The shunt resistor R may cause the control circuit unit 150 to feed back the second current I2.

The control circuit unit 150 is connected between the shunt resistor R and the output terminal of the switch Q or source so as to check whether the overcurrent flows according to the divided voltage for the second current I2 and the first current I1 The overcurrent protection unit 152 and the overcurrent protection unit 152 are connected in parallel between the gates of the switches Q to prevent the breakage of the switch Q when the overvoltage is supplied to the LED load 110 The overvoltage protection unit 154 may be provided.

That is, the overcurrent protection unit 152 is connected between the distribution resistors R1 and R2 and the distribution resistors R1 and R2 for detecting the overcurrent of the second current I2 and is connected to the distribution resistors R1 and R2 Off current I1 supplied to the output terminal of the inductor L of the switching off state of the overcurrent shutoff unit Q1 and the overcurrent shutoff unit Q1 which is switched on or off according to the applied divided voltage V1, (Q) is switched on.

The overvoltage protection unit 154 includes a zener diode ZD for allowing the dc power source Vdc to flow when the dc power source Vdc output to the output terminal of the inductor L is an overvoltage, And a voltage cutoff unit Q2 for applying a power supplied from the overcurrent protection unit 152 to the ground so that the switch Q is switched on by operating the input dc power supply Vdc.

In the embodiment, the overcurrent shutoff unit Q1 and the overvoltage shutoff unit Q2 may be at least one of the FET and the BJT like the switch Q, but are not limited thereto.

As described above, the LED driver circuit 100 controls the switch Q to be switched on so as to initially form the first current path using the first current I1 charged in the inductor L Turns off the switch Q according to the second current I2 output from the switch Q after the first current path is formed so that the first current I1 charged in the inductor L is applied to the LED load 110 The LED load 110 can be controlled to be supplied with a stable first current I1, that is, a constant current.

Fig. 3 is a current path diagram showing a first current path of the LED driver circuit according to the embodiment; and Fig. 4 is a current path diagram showing a second current path of the LED driver circuit according to the embodiment.

3, the LED driving circuit 100 supplies the first current I1 previously charged to the inductor L to the overcurrent control unit 152 at the time of supplying the ac power source Vac to the rectifying unit 120 .

At this time, the overcurrent protection unit 152 supplies a switch-on signal that causes the first current I1 to switch on through the arbitrary resistance element.

The switch Q4 is switched on in response to the switch-on signal input through the overcurrent protection unit 152 so that the dc power source Vdc rectified in the rectification unit 120 is connected to the LED load 110, the inductor L, (Q4) and the shunt resistor (R) to form a first current path (ps1) to ground.

At this time, the overcurrent protection unit 152 feedbacks the second current I2 flowing between the switch Q4 and the shunt resistor R to confirm whether or not the overcurrent flows.

Thereafter, when the overcurrent protection unit 152 is not overcurrent, the switch Q4 can supply the first current I1 and the switch-on signal by the arbitrary resistance element.

In addition, the overvoltage protection unit 154 prevents the switch-on signal from being cut off when the voltage flowing through the inductor L is not an overvoltage.

4, the LED driving circuit 100 supplies the first current I1 charged in the inductor L1 to the LED load 110 via the diode D when the switch Q is switched off, That is, the second current path ps2.

In this case, the second current path ps2 is connected to the second current path I2, which is fed back to the overcurrent protection unit 152 by the first current path ps1 in Fig. 3, from the distribution voltage The overcurrent shutoff unit Q1 is turned on in accordance with the voltage V1 and the switch-on signal supplied to the switch Q is supplied to the ground.

The LED driving circuit 100 according to the embodiment allows the LED load 100 to supply the rectified dc power or the first current to the rectifying part 120 based on the first current charged in the inductor L, There is an advantage that a constant current can be supplied to the LED load 110 instead of an expensive component such as a constant current drive integrated circuit or a microprocessor.

The embodiments of the present invention are not intended to limit the scope of the present invention but to limit the scope of the present invention. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

Claims (10)

LED load;
a rectifying section for rectifying the ac power source to the dc power source;
A driving unit for forming a first current path for receiving the dc power as the LED load and for charging the first current outputted from the LED load; And
A control circuit part for protecting the overcurrent and the overvoltage based on the second current fed back from the output terminal of the driving part and the first current during the formation of the first current path and controlling the driving part to form the first current path, Including an LED drive circuit. The method according to claim 1,
And a filter unit disposed between the rectifying unit and the LED load for filtering the dc power supply, 3. The method of claim 2,
The filter unit includes:
An LED driver circuit that is an LC filter. The method according to claim 1,
The rectifying unit includes:
And a bridge diode for rectifying the phase of the ac power source to the dc power source inverted in phase. The method according to claim 1,
The driving unit includes:
An inductor for charging the first current outputted to the output terminal of the LED load;
A diode coupled between the output of the inductor and the input of the LED load; And
And a switch connected in parallel to the inductor and the diode, the switch being operated under the control of the control circuit. 6. The method of claim 5,
Wherein the first current path comprises:
Wherein the switch is a current path through which the second current is output through the LED load, the inductor, and the switch when the switch is turned on. 6. The method of claim 5,
The inductor includes:
And a second current path for supplying the first current to the LED load through the diode in a switching-off operation under the control of the control circuit section. 6. The method of claim 5,
Wherein the switch comprises:
And at least one of an FET and a BJT. 6. The method of claim 5,
The driving unit includes:
And a shunt resistor connected between the output terminal of the switch and the ground for feeding back the second current. LED load:
a rectifying section for rectifying the ac power source to the dc power source;
A driving unit for forming a first current path for receiving the dc power as the LED load and for charging the first current outputted from the LED load; And
And a control circuit unit controlling the driving unit so that the first current path is formed and controlling the driving unit so that the first current outputted from the LED load is blocked based on the second current fed back from the output terminal of the driving unit and,
Wherein the control circuit unit includes:
And controls the driving unit to input the dc power to the LED load based on the first current charged from the driving unit to initialize the LED load to form the first current path.

Images